I don't grasp the full complexity of the counting hierarchy $CH$. I understand $CH$ is in $PSPACE$, and contains $PH$ within its second level, due to the Toda's theorem. But, what would be important ...

The complexity of computing the permanent of a $l\times l$ binary matrix is known to be $\#\mathsf{P}$-complete, from the famous result of Valiant, where $l = \Theta(n)$.
We know that the problem is ...

Contained in-between each level of the polynomial hierarchy are various complexity classes, including $\Delta_i^{\text{P}}$, $\text{DP}$, $\text{BH}_k$, and $\Sigma_i^\text{P} \cap \Pi_i^\text{P}$. ...

Meyer's theorem is one of the classical results about collapse of the polynomial hierarchy such as famous Karp Lipton's theorem, and states that $EXP \subseteq P/poly \Rightarrow EXP = \Sigma_{2}^{p} ...

It is well known that if $\mathbf{P}=\mathbf{NP}$ then the polynomial hierarchy collapses and $\mathbf{P}=\mathbf{PH}$.
This can easily be understood inductively using oracle machines.
The question ...

Given a non-deterministic Turing Machine that runs in polynomial time, it accepts if the number of accepting paths are composite, it rejects if the number of accepting paths are prime and it outputs I ...

Finding whether or not a QBF can be satisfied is a canonical complete problem for both $\Sigma^P_n$ (start from $\exists$) and $\Pi^P_n$ (start from $\forall$). What is the canonical complete problem ...

We know that the first level of the polynomial hierarchy (i.e. NP and co-NP) is in PP, and that $PP \subseteq PSPACE$. We also know from Toda's Theorem that $PH \subseteq P^{PP}$.
Do we know whether ...